Light enhanced flow tube

ABSTRACT

An improved fluid flow gauging device includes a light enhanced acrylic block flow tube to optimize visualization of pressure readings. An LED or other light source is fitted to the top of the flow tube and illuminates a float or bobbin from above to provide more accurate readings, especially in low light conditions such as modern operating rooms. In addition, the light enhanced flow tube provides a mechanical backup in the case of failure of newer electronic systems and visually matches the graphical flow display, simultaneously providing a double-check of the electronic system.

CROSS REFERENCE OF THE INVENTION

The present invention relies on U.S. Provisional Application No.61/252,269, filed on Oct. 16, 2009, for priority, and incorporates thespecification and drawings of this application by reference in itsentirety.

FIELD OF THE INVENTION

The present invention relates to gas and liquid flow gauging devices.More particularly, the present invention relates to a light enhancedflow tube with a bobbin used as a measure of flow in anesthesia systems.

BACKGROUND OF THE INVENTION

Historically, transparent tubes containing a float or “bobbin” have beenused as a means of measuring flow in gas and liquid systems. Visuallyobserving the level of the bobbin alongside scaled markings on a plasticstrip adjacent to the tube or printed on the walls of the tube itself,enables users to accurately gauge the flow of gas or liquid beingapplied to the system. Traditionally, such gauging devices have utilizedan elongated illumination source positioned behind the flow tube andscale strip. While providing an extremely reliable means for measuringflow, this traditional method is difficult to read accurately and doesnot provide for optimal visualization when used in low light conditions,such as those found in today's operating rooms.

Lengthwise illumination of the flow tube along with illumination of aneedle gauge has been used to assist the user in taking readings. Forexample, United States Patent Application Number 20080251003, assignedto Aviation Oxygen Systems, Inc., describes “[a]n illuminated gas flowtube comprises an in-line flow tube having a distal end and a proximalend. A gas inlet is co-axially secured to the distal end, and a gasoutlet is co-axially secured to the proximal end. A specific gravityball is located within the in-line flow tube, and moves within the flowtube as a function of gas entering the gas inlet. A phosphorescent orphotoluminescent material is configured and arranged to at leastpartially lengthwise surround a radial exterior portion of the flow tubeto illuminate the interior of the tube. An illuminated gas pressuregauge comprises an gas inlet, a pressure sensing element, a transparentcover, and a face that is encased by and seen through the transparentcover, where the face includes markings indicative of pressure. A needleis operatively connected to the pressure sensing element and seenthrough the transparent cover to provide a visual indication of pressureat the gas inlet, where the face is coated with an illuminating materialthat allows the gauge to be read in low light conditions.”

In addition, newer flow gauging devices, specifically those used inmodern anesthesia machines, now use electronic flow measurement anddisplay the data graphically on a video user interface. These newersystems have the advantage of providing digital outputs and enabling theuser to directly input the flow data into the patient's records.

Although these new electronic devices provide accurate and visuallyappealing flow data, a need exists to provide a reliable flow tubedevice that works via a mechanical method in the event of electronicsystem failure. The user will also desire the mechanical flow tube as a“double check” of the digital data. In addition, the mechanical flowtube device needs to display the flow data in a manner that matchesnewer electronic displays and can be read optimally in low lightconditions.

SUMMARY OF THE INVENTION

In one embodiment, the present invention is a light enhanced flow tubewith a bobbin used as a measure of flow in anesthesia systems.

In one embodiment, the present invention is a fluid flow gauging devicecomprising a container encasing a hollow tube having a length, a bottomand a top, wherein an inlet port is positioned proximate to the bottomof the hollow tube, wherein an opening is positioned proximate to thetop of the hollow tube, and wherein an outlet port is positionedproximate to the top of the hollow tube; a bobbin located within thehollow tube, said bobbin capable of traversing the length of the hollowtube dependent upon the amount of fluid pressure applied; and a fiberoptic pipe used to direct light from a light source through the top ofsaid hollow tube and toward said bobbin.

In one embodiment, the bobbin is spherical and has a reflective quality.In one embodiment, the bobbin is a white alumina ceramic ball. Inanother embodiment, the bobbin is a stainless steel ball.

In one embodiment, said container comprises at least one unitary pieceof acrylic, wherein said unitary piece of acrylic is an acrylic block.Additionally, said container comprises at least one beveled face havinga plurality of scale markings proximate to said at least one beveledface.

In one embodiment, the fiber optic pipe is fixedly attached to saidopening positioned proximate to the top of the hollow tube. In oneembodiment, the light source comprises a remotely located LED, whereinsaid LED is powered by an energy source independent of an energy sourcethat causes a flow of fluid through said hollow tube.

In one embodiment, the inlet port is configured to receive pressurizedgas into said hollow tube and the outlet port is configured to enable anexit of said pressurized gas from said hollow tube. In one embodiment,the tube is cylindrical.

In one embodiment, a mechanism automatically switches on said lightsource when fluid flows. In one embodiment, said mechanism comprises apressure transducer measuring the pressure rise through the resistanceof the flow meter. In another embodiment, said mechanism comprises aswitch on the flow control needle valve. In one embodiment, when fluidis caused to flow through said hollow tube, said fiber optic pipeilluminates a top hemisphere of said bobbin.

In another embodiment, the present invention is a fluid flow gaugingdevice comprising a container encasing a hollow tube having a length, abottom and a top, wherein an inlet port is positioned proximate to thebottom of the hollow tube, wherein an opening is positioned proximate tothe top of the hollow tube, and wherein an outlet port is positionedproximate to the top of the hollow tube; a bobbin located within thehollow tube, said bobbin capable of traversing the length of the hollowtube dependent upon the amount of fluid pressure applied; and a lightemitting diode (LED) used to project light through the top of saidhollow tube and toward said bobbin.

In yet another embodiment, the present invention is a fluid flow gaugingdevice comprising a container encasing a hollow tube having a length, abottom and a top, wherein an inlet port is positioned proximate to thebottom of the hollow tube, wherein an opening is positioned proximate tothe top of the hollow tube, and wherein an outlet port is positionedproximate to the top of the hollow tube; a bobbin located within thehollow tube, said bobbin capable of traversing the length of the hollowtube dependent upon the amount of fluid pressure applied; and a lightsource directed through the top of said hollow tube and toward saidbobbin.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other features and advantages of the present invention will beappreciated, as they become better understood by reference to thefollowing detailed description when considered in connection with theaccompanying drawings, wherein:

FIG. 1 is a three-dimensional diagram illustrating a number of thecomponents of the light enhanced flow tube of the present invention;

FIG. 2A is an illustration of the top view of the light enhanced flowtube, depicting the opening for a light pipe and various measurementsincluded in one embodiment of the present invention;

FIG. 2B is an illustration of the bottom view of the light enhanced flowtube, depicting an inlet port and various measurements included in oneembodiment of the present invention;

FIG. 2C is an illustration of the back view of the light enhanced flowtube, depicting an outlet port and various measurements included in oneembodiment of the present invention;

FIG. 2D is an illustration of the front face view of the light enhancedflow tube, depicting the beveled front face, beveled right side, andvarious measurements included in one embodiment of the presentinvention;

FIG. 3 is an illustration of the right side profile view of the lightenhanced flow tube;

FIG. 4 is a diagram separately illustrating a number of the componentsof the fiber optic light pipe assembly;

FIG. 5 is a diagram illustrating a fully assembled fiber optic lightpipe assembly;

FIG. 6 is an illustration of a close-up view depicting the transitionfrom light to dark of the illuminated bobbin adjacent to an electronicgraphical flow display;

FIG. 7 is an illustration of one embodiment in which the light enhancedflow tube has been attached to an anesthesia machine adjacent to anelectronic graphical flow display; and,

FIG. 8 is an illustration of a straight on view of one embodiment inwhich the light enhanced flow tube has been attached to an anesthesiamachine adjacent to an electronic graphical flow display.

DETAILED DESCRIPTION

In one embodiment, the present invention is directed towards an improvedfluid flow, such as any gas or liquid, gauging device in the form of alight enhanced flow tube.

In one embodiment, the present invention is directed towards a flow tubeencased in an acrylic block, said flow tube containing a float or“bobbin”, said bobbin being illuminated from the top in an effort toenhance visualization of the bobbin, thereby enabling the user to makemore accurate flow readings. The illumination is supplied via a lightemitting diode (LED) or other light source and shines down from the topof the tube onto the bobbin. In one embodiment, the bobbin is sphericaland of a reflective material so as to enhance visualization whenilluminated from above. The prismatic effect of the acrylic block flowtube combined with the illumination of the bobbin allow for clearervisualization of the bobbin level and therefore more accurate flowreadings, especially in low light conditions. The combined effects alsoallow the user to make accurate flow readings at more extreme viewingangles relative to front face of a traditional flow tube.

Further, the present invention is directed towards the use of aspherical, white alumina ceramic indicator ball as the bobbin. Thisparticular type of bobbin reflects blue light from an LED driven lightpipe in a visually appealing manner. The white alumina ceramic indicatorball does so by “spreading” light around its surface, illuminating thewhole upper hemisphere. This type of bobbin enhances visualization moreeffectively than a stainless steel ball, which reflects light more as apoint. In addition, since the reflected light spreads over the entireupper hemisphere, it forms a natural light to dark line at the center ofthe ball, exactly where the user should take the visual flow reading.

Still further, the angled face flow tube design allows for optimalviewing when the light enhanced flow tube is mounted on an anesthesiamachine adjacent to the electronic flow tube screen. This inventionprovides an updated implementation of older flow tube technology,offering the user better visualization of the bobbin whilesimultaneously providing a better visual convergence of newer electronicflow measurement displays and older flow tube technology used as abackup measurement source. The angled face flow tube design allows forthe floating illuminated sphere to be viewed from directly in front ofthe electronic flow tube screen even though the bezel for the frontdisplay is physically in between the bobbin and the user's eyes. Thebend of light at the angled face allows this visualization to occur andkeeps the area consumed by the front face of the flow tube small.

Still further, the light used to illuminate the bobbin is supplied via afiber optic light pipe that is introduced into a sealed fitting at thetop of the flow tube. This allows the source LED to be mounted on acircuit board some distance removed from the flow tube, enabling moreeconomical and practical packaging.

Still further, the illumination would only be turned on when flow isbeing applied to the system. This could be effectuated with a separateelectronic mechanism. This will result in the added benefit ofinformation projection lighting. If the flow is turned on, the bobbinwill automatically illuminate, resulting in enhancing the bobbin readingbecause of the light. In addition, operating rooms and other areas ofhospitals often have auxiliary oxygen flow tubes that will waste O₂ gasif mechanically left on. By having the illumination turned on only whenflow is applied, the user will be able to observe if the bobbin isilluminated and know that the flow has been inadvertently left on.

The present invention is directed towards multiple embodiments. Thefollowing disclosure is provided in order to enable a person havingordinary skill in the art to practice the invention. Language used inthis specification should not be interpreted as a general disavowal ofany one specific embodiment or used to limit the claims beyond themeaning of the terms used therein. The general principles defined hereinmay be applied to other embodiments and applications without departingfrom the spirit and scope of the invention. Also, the terminology andphraseology used is for the purpose of describing exemplary embodimentsand should not be considered limiting. Thus, the present invention is tobe accorded the widest scope encompassing numerous alternatives,modifications and equivalents consistent with the principles andfeatures disclosed. For purpose of clarity, details relating totechnical material that is known in the technical fields related to theinvention have not been described in detail so as not to unnecessarilyobscure the present invention.

FIG. 1 is a three dimensional diagram illustrating a number of thecomponents of the light enhanced flow tube 14. In one embodiment, thelight enhanced flow tube 14 is contained within an acrylic block 10.Further, flow tube 14 comprises an inlet port 17 positioned at thebottom of the acrylic block 10, an outlet port 19 exiting to the back ofthe acrylic block 10, an opening 18 for a sealed fitting for a fiberoptic light pipe, and a bobbin 12 located within flow tube 14. Thebobbin 12 can be any structure capable of floating in a fluid flow,including a float, a bob, a buoyant particle, or any other suchstructure. In one embodiment, the acrylic block 10 has a mounting hole16 positioned at the top and a mounting hole 15 positioned at thebottom. In one embodiment, the acrylic block 10 has five sides,comprising a left side, a back side, a non-beveled portion of the rightside 22, a beveled right side 20, and a beveled front face 24 tooptimize visualization of bobbin 12.

In one embodiment, the acrylic block 10 has a beveled front face 24 anda partially beveled right side 20 to enhance visualization of the bobbin12 from multiple and extreme viewing angles. FIG. 2A is an illustrationof the top view of the light enhanced flow tube 14, depicting theopening for a light pipe 18 and various measurements included in oneembodiment of the present invention. In one embodiment, the back side 28of acrylic block 10 measures 24.00 millimeters across and forms a 90degree angle with the left side 26 when facing the front face 24 of theacrylic block 10. In one embodiment, the left side 26 measures 30.27millimeters. In an additional embodiment, the left side 26 and back side28 of the flow tube arc covered with an opaque label or ink ofcontrasting color to further enhance the visual effect of the bobbin'sillumination. In one embodiment, this color is a light grey. In oneembodiment, the non-beveled portion of the right side 22 when facing thefront face 24 forms a 90 degree angle with the back side 28 of theacrylic block 10 and measures 14.37 millimeters. In one embodiment, thebeveled portion of the right side 20 forms a 37+/−2 degree angle withthe non-beveled portion of the right side 22 and extends inward towardthe left side 26 of the acrylic block 10. In one embodiment, the beveledfront face 24 forms an 82.54+/−2 degree angle with the left side 26 andextends outward away from the center of the acrylic block 10.

As shown in FIG. 2A, in one embodiment, the center of the flow tube 14is positioned 9.00 millimeters in from the left side 26 when facing thefront face 24 and 16.00 millimeters in from the back of the acrylicblock 10. In one embodiment, the flow tube 14 extends substantially fromthe bottom of the acrylic block 10 to substantially to the top of theacrylic block 10, where an opening for a sealed fitting 18 for a fiberoptic light pipe is located. In one embodiment, the opening 18 for thelight pipe is ¼ inch diameter British Standard Pipe Parallel thread(BSPP) and extends vertically at least 12.00 millimeters down into theacrylic block 10. In one embodiment, the center of the opening 18 forthe light pipe at the top of the acrylic block 10 is positioned 9.00millimeters in from the left side 26 when facing the front face 24 and16.00 millimeters in from the back side 28 of the acrylic block 10, inline with the center of the flow tube 14. The flow tube 14 is wider atthe top and narrower at the bottom, with its cross section varying as afunction of calibration gas and the weight of the bobbin 12. The bobbin12 traverses the length of the flow tube 14 up to the light pipe lens atthe top and down to the narrower portion at the bottom. The lens at thetop of the flow tube 14 prevents further travel of the bobbin 12 up theflow tube 14 and the smaller diameter at the bottom of the flow tube 14prevents further travel of the bobbin 12 down the flow tube 14. Thebobbin 12 traverses up and down the flow tube 14 dependent upon theamount of flow passing through the flow tube 14. In one embodiment, amounting hole 16 is positioned at the top of the acrylic block 10. Inone embodiment, the mounting hole 16 at the top of the acrylic block 10is 2.50 millimeters in diameter and extends vertically at least 12.00millimeters down into the acrylic block 10. In one embodiment, thecenter of the mounting hole 16 at the top of the acrylic block 10 ispositioned 5.00 millimeters in from the left side 26 when facing thefront face 24 and 5.00 millimeters in from the back side 28 of theacrylic block 10.

FIG. 2B is an illustration of the bottom view of the light enhanced flowtube 14, depicting the inlet port 17 and various measurements includedin one embodiment of the present invention. The inlet port 17 is locatedat the bottom of the acrylic block 10 and serves to receive pressurizedgas into the flow tube 14. As shown in FIG. 2B, in one embodiment, theinlet port 17 positioned at the bottom of the acrylic block 10 is ⅛ inchdiameter BSPP and extends vertically at least 7.00 millimeters up intothe acrylic block 10. In one embodiment, the center of the inlet port 17is positioned 9.00 millimeters in from the left side 26 when facing thefront face 24 and 16.00 millimeters in from the back side 28 of theacrylic block 10, in line with the center of the flow tube 14. In oneembodiment, a mounting hole 15 is positioned at the bottom of theacrylic block 10. In one embodiment, the mounting hole 15 at the bottomof the acrylic block 10 is 2.50 millimeters in diameter and extendsvertically at least 12.00 millimeters up into the acrylic block 10. Inone embodiment, the center of the mounting hole 15 at the bottom of theacrylic block 10 is positioned 5.00 millimeters in from the left side 26when facing the front face 24 and 5.00 millimeters in from the back side28 of the acrylic block 10.

FIG. 2C is an illustration of the back view of the light enhanced flowtube 14, depicting the outlet port 19 and various measurements includedin one embodiment of the present invention. The outlet port 19 islocated on the back of the acrylic block 10 and serves as a point forthe pressurized gas to exit the flow tube 14. As shown in FIG. 2C, inone embodiment, the outlet port 19 exiting to the back of the acrylicblock 10 is ⅛ inch diameter BSPP and extends horizontally at least 7.00millimeters into the acrylic block 10 at which point it connects withthe flow tube 14. In one embodiment, the center of the outlet port 19 ispositioned 9.00 millimeters in from the left side 26 when facing thefront face 24 and 26.50 millimeters down from the top of the acrylicblock 10.

FIG. 2D is an illustration of the front face view of the light enhancedflow tube 14, depicting the beveled front face 24, beveled right side20, and various measurements included in one embodiment of the presentinvention. As shown in FIG. 2D, in one embodiment, the total length ofthe acrylic block 10 measures 160.00 millimeters. With reference toFIGS. 2A and 2D simultaneously, in one embodiment, for the first 25millimeters from the top of the acrylic block 10, the beveled portion ofthe right side 20 recedes 2.00 millimeters back toward the center of theacrylic block 10. After the first 25.00 millimeters, the beveled rightside 20 extends back outward 2.00 millimeters and continues at thismeasurement for another 115.00 millimeters. At this point, the beveledright side 20 again recedes 2.00 millimeters back towards the center ofthe acrylic block 10 and continues in this manner another 20.00millimeters to the bottom of the acrylic block 10. Further, in oneembodiment, for the first 25 millimeters from the top of the acrylicblock 10, the beveled front face 24 recedes 2.42 millimeters back towardthe center of the acrylic block 10. After the first 25.00 millimeters,the beveled front face 24 extends back outward 2.42 millimeters andcontinues at this measurement for another 115.00 millimeters. At thispoint, the beveled front face again recedes 2.42 millimeters backtowards the center of the acrylic block 10 and continues in this manneranother 20.00 millimeters to the bottom of the acrylic block 10.

In one embodiment, the fully extended beveled front face and fullyextended beveled portion of the right side are polished and all theremaining surfaces are semi-opaque or fully opaque and contain acontrasting color. The polished surfaces and bending of light at thesebeveled faces allows optimal visualization while simultaneously keepingthe area consumed by the front face of the light enhanced acrylic blockflow tube relatively small when positioned adjacent to the electronicgraphical display.

In one embodiment, the light enhanced acrylic block flow tube iscalibrated for O₂ gas and is chemically compatible with O₂, N₂O, andair. In one embodiment, the pressure range is 0-14 kPa GA and the flowrange is 0-15 LPM.

FIG. 3 is an illustration of the right side profile view of the lightenhanced flow tube 14. In one embodiment, the beveled right side 20contains white scale markings at 0, 5, 10, and 15 LPM, with ticks every1 LPM. The scale markings include a ‘Read at Center’ symbol and a‘L/Min’ label. In one embodiment, only the fully extended beveled rightside 20 contains markings and the scale usable range spans a minimum of75% of the full height of said fully extended beveled right side 20.

FIG. 4 is a diagram separately illustrating a number of the componentsof the fiber optic light pipe assembly 30, as shown assembled in FIG. 5.In one embodiment, the fiber optic light pipe assembly includes a fiberoptic pipe 34 that terminates with a lens 32 on one end and connects toan LED on the other end. This allows the source LED to be mounted on acircuit board remote from the flow tube, enabling more economical andpractical packaging. In one embodiment, the fiber optic pipe 34 isencircled by a plug top 38 that has a thread fitting that matches thetop opening of the acrylic block. In one embodiment, an o-ring or washer36 is positioned between the plug top 38 and the opening at the top ofthe acrylic block. A smaller o-ring or washer 37 is positioned above theplug top 38. In one embodiment, a silicone based adhesive sealant isapplied to completely cover the o-ring or washer 37 and around the fiberoptic pipe 34 where the two meet to ensure a secure fitting of the fiberoptic pipe 34 to the plug top 38. In one embodiment, the silicone basedadhesive sealant should not extend past 8 millimeters above the plug top38 surface.

FIG. 5 is a diagram illustrating a fully assembled fiber optic lightpipe assembly 30. The remotely mounted LED emits light into the fiberoptic pipe 34 which transmits the light to lens 32 which in turn caststhe light onto the bobbin, effectuating illumination of the upperhemisphere of said bobbin.

In one embodiment, the LED would only turn on when flow is applied tothe flow tube. This would be accomplished via a separate electronicmechanism. In one embodiment, this is accomplished through the use ofseparate electronic flow sensors, including a pressure transducermeasuring the pressure rise through the resistance of the flow meter. Inanother embodiment, this mechanism can be accomplished via a switch onthe flow control needle valve. This ensures that the illuminationautomatically turns on when flow is applied and automatically turns offwhen flow terminates, thereby helping to prevent flow systems from beinginadvertently left on. This behavior has specific application to“auxiliary oxygen flow control” devices commonly used in anesthesiathat, by design, are not decoupled from the oxygen supply when theanesthesia system is turned off.

Referring back to FIG. 1, the light enhanced flow tube 14 contains abobbin 12 that is free to traverse the length of the flow tube 14. Inone embodiment, the bobbin 12 is a substantially spherical white aluminaceramic ball. In one embodiment, the bobbin is ¼ inch in diameter. Thewhite alumina ceramic has a more reflective quality than moretraditional compositions, resulting in the light being spread over theentire upper hemisphere of the ball.

FIG. 6 is an illustration of a close-up view depicting the transitionfrom light to dark of the illuminated bobbin 12 adjacent to anelectronic graphical flow display 40. As shown in FIG. 6, theillumination of the entire upper hemisphere results in a light to darkline forming substantially at the middle of the bobbin 12, preciselywhere a user will take a visual flow reading. Therefore, when the LEDtransmits a light wave through the fiber optic pipe and out from thelens, it causes the upper portion of the bobbin to brighten which,relative to the lower portion of the bobbin, causes the creation of asolid light-based visual demarcation which can be used to accuratelyidentify a level.

FIG. 7 is a three dimensional diagram illustrating one embodiment inwhich the light enhanced flow tube 10 has been attached to an anesthesiamachine adjacent to an electronic graphical flow display 40. Inparticular, it is advantageous to use flow tube designs in anesthesiaapplications as a back-up or an error checking device. The user willdesire a mechanical device in the event of electronic failure and alsoas a means of coarsely spot checking readings against the graphicaldisplay. The angled face design of the acrylic block and the choice of awhite alumina ceramic indicator ball as a bobbin enhance theeffectiveness of the invention. Also, the use of the angled acrylicblock surfaces allows for full visibility of the bobbin for the user butdoes not impinge on the front face geometry necessary for the bestpresentation of the graphical user interface.

FIG. 8 is an illustration of a straight on view of one embodiment inwhich the light enhanced flow tube 14 has been attached to an anesthesiamachine adjacent to an electronic graphical flow display 40. As shown inFIG. 8, in one embodiment, mounting the light enhanced flow tube 14 tothe side of the electronic graphical flow display 40 allows the user toread both the electronic display and the mechanical bobbinsimultaneously. In addition, the relatively small space occupied by thelight enhanced acrylic block flow tube when viewed from the front allowsthe user to focus on the graphical display and use the mechanicalreading as a back-up. The illuminated bobbin 12 seemingly matches thevisuals provided by the graphical display 40, providing a convergence ofold and new technologies.

In one embodiment, the light emitted by the LED is colored blue, in aneffort to most closely match the visuals provided by the graphicaldisplay 40.

In another embodiment, the bobbin is a spherical stainless steel ball.When used as a bobbin, the stainless steel ball reflects the light fromthe LED as a single point.

In another embodiment, the light enhanced flow tube of the presentinvention can be used in any environment that is dark and/or dirty,thereby requiring an enhanced readability component. In addition, usingthe light enhanced flow tube in a dark and/or dirty environment wouldenable the user to assess the flow level at a glance.

In another embodiment, the light enhanced flow tube of the presentinvention can be used in any environment in which the flow tube needs tobe read at some distance. The enhancement resulting from theillumination gives the user a sharper image of the relative readout withrespect to the full height of the flow tube.

In another embodiment, the light enhanced flow tube of the presentinvention can be used in a household environment. The light enhancedflow tube can be used to enhance visualization of furnace flow levels,air conditioner flow levels, and radon remediation flow tubes (pullsuction from under the house's foundation). In addition, these devicesare often in darkened basements and so would benefit from the enhancedvisualization afforded by the present invention in dark environments.

In another embodiment, the light enhanced flow tube of the presentinvention can be used in industrial environments. The light enhancedflow tube can be used in various types of fluid float applications usingboth liquids and gases. These environments can also be dark and/or dirtyand the user would benefit from the light enhancement.

In another embodiment, the light enhanced flow tube of the presentinvention can be used in chemical applications. In another embodiment,the light enhanced flow tube of the present invention can be used inresearch applications. In another embodiment, the light enhanced flowtube of the present invention can be used in clean food processingapplications.

Although certain illustrative embodiments and methods have beendisclosed herein, it will be apparent from the foregoing disclosure tothose skilled in the art that variations and modifications of suchembodiments and methods may be made without departing from the spiritand scope of the invention. Accordingly, it is intended that theinvention should be limited only to extent required by the appendedclaims and the rules and principals of applicable law.

The invention claimed is:
 1. A method of operating a fluid flow gaugingdevice to measure a flow of fluid, the method comprising: generatinglight from a source LED; transmitting said light through a fiber opticpipe, wherein said fiber optic pipe terminates in a lens; passing saidlight through said lens and into a top of a hollow tube, wherein saidhollow tube has a length, a bottom and a bobbin and wherein the fluidflow gauging device comprises at least one unitary block of acrylichaving a plurality of elongated sides parallel to the length of thehollow tube; and illuminating said bobbin, wherein the bobbin is adaptedto traverse the length of the hollow tube based on an amount of fluidpressure applied.
 2. The method of claim 1, wherein the source LED ispositioned remote from the fluid flow gauging device.
 3. The method ofclaim 1, further comprising positioning the fluid flow gauging deviceadjacent an electronic graphical flow display.
 4. The method of claim 1,wherein the light is blue and said bobbin is a spherical stainless steelball.
 5. The method of claim 1, wherein the light is blue and saidbobbin comprises white alumina ceramic.
 6. The method of claim 1,wherein the light is white and said bobbin comprises white aluminaceramic.
 7. The method of claim 1, further comprising automaticallyswitching on the source LED when fluid flows.
 8. The method of claim 1,comprising measuring a pressure rise of the fluid using a pressuretransducer.
 9. The method of claim 1, wherein one of said plurality ofsides is a front face having a beveled portion.
 10. The method of claim9, wherein one of said plurality of sides is a side face having abeveled portion.
 11. The method of claim 1 wherein the hollow tubefurther comprises an inlet port configured to receive pressurized gasinto said hollow tube.
 12. The method of claim 11 wherein the hollowtube further comprises an outlet port configured to enable an exit ofsaid pressurized gas from said hollow tube.